When the human mind is free to roam, its subjective experience is characterized by a continuously evolving stream of thought. Although there is a technique that captures people's streams of free thought-free association-its utility for scientific research is undermined by two open questions: (a) How can streams of thought be quantified? (b) Do such streams predict psychological phenomena? We resolve the first issue-quantification-by presenting a new metric, "forward flow," that uses latent semantic analysis to capture the semantic evolution of thoughts over time (i.e., how much present thoughts diverge from past thoughts). We resolve the second issue-prediction-by examining whether forward flow predicts creativity in the lab and the real world. Our studies reveal that forward flow predicts creativity in college students (Study 1) and a representative sample of Americans (Study 2), even when controlling for intelligence. Studies also reveal that membership in real-world creative groups-performance majors (Study 3), professional actors (Study 4) and entrepreneurs (Study 5)-is predicted by forward flow, even when controlling for performance on divergent thinking tasks. Study 6 reveals that forward flow in celebrities' social media posts (i.e., on Twitter) predicts their creative achievement. In addition to creativity, forward flow may also help predict mental illness, emotional experience, leadership ability, adaptability, neural dynamics, group productivity, and cultural success. We present open-access online tools for assessing and visualizing forward flow for both illustrative and large-scale data analytic purposes.
Contributions of various biochemical processes to overall energy expenditure in the gastrointestinal tract (GIT) and liver have been assessed in this review. The GIT and liver are responsible for a disproportionately high fraction of whole-body energy utilization. The energetic cost of Na+, K(+)-ATPase, protein synthesis and degradation, substrate cycling and urea synthesis contribute substantially to energy expenditure in the ruminant. In the splanchnic bed, these biochemical processes account for approximately 22.8% of whole-body O2 and, consequently, ATP utilization; they are influenced by several factors, including dietary composition, level of intake, age, endocrine status and physiological state. In the GIT and liver, the energetic cost of Na+, K(+)-ATPase is by far the most energetically demanding process; it is related to the active transport of substrates and the maintenance of ionic homeostasis. The high rate of protein synthesis in the GIT is associated with cellular turnover and sloughing, secretion and enzymatic action. In the liver, protein synthesis is important in the mediation of hormonal induction, which influences regulation of body systems, synthesis of plasma proteins, enzymatic and cellular turnover and detoxification of blood. Regulation of these processes and the signals involved in the differential contribution of each biochemical event are not well understood. The large contribution of these biochemical events in the GIT and liver to whole-animal energy utilization suggests that their manipulation may alter the energetic efficiency of meat, milk or wool production.
Vegetative buffers have been shown to reduce nutrient loss associated with the transport of detached soil particles and may through plant uptake offer a means to capture dissolved nutrients moving to surface waters through the soil solution. The objective of this 4-year study was to evaluate changes in the biomass and P content of the roots and shoots of plants growing in a multispecies versus a single species riparian buffer as an index of P capture potential. Periodic harvests of above ground vegetation were combined with root cores to estimate the total standing biomass and the pool of P in plant tissue in three vegetative cover types dominated by either switchgrass (Panicum virgatum L.), an alfalfa (Medicago sativa L.)-smooth bromegrass (Bromis inermis Leyss) mix, or a fast growing superior cottonwood (Populus deltoids Bartr., clone 42-7). An existing stand of smooth brome served as the single species control. Standing biomass increased in all three cover types during the 4 years of study, with the greatest increases observed in the cottonwood (2345 g m -2 ) and switchgrass (1818 g m -2 ). Biomass production in the smooth brome control did not change during the study period. Based on the 4th-year samples, standing pools of P closely paralleled total plant biomass and root surface area with cottonwood accumulating the greatest amount of P at 19.4 g m -2 compared to 4.3 g m -2 for the smooth brome control. Estimates of potential P export via biomass harvest from a mixed buffer over a 4-year interval were 101 kg ha -1 compared to 62 kg ha -1 for the smooth brome control; a 63% increase in export capacity due largely to the inclusion of cottonwood. Addition of a fast growing woody species combined with periodic biomass harvests has the potential to reduce P movement to surface waters.
Biospheric ozone has become a widely distributed air pollutant, and a growing body of research indicates that ozone impacts forest health and productivity. Ozone effects are mediated by the ozone concentration present in the external environment and the movement of ozone into the leaf via the stoma. The cumulative dose received by the plant is, in the simplest terms, a function of ambient ozone concentration and stomatal conductance to water vapor. This relationship is important in understanding ozone flux into the leaf and subsequent ozone response in plants. Here, current progress in understanding ozone uptake in juvenile and mature trees is examined. Through an analysis of two long‐term case studies, the significant uncertainty in assessing ozone effects on forests is pinpointed to be the scaling of ozone sensitivity from controlled seedling studies to large forest trees. A rigorous statistical and monitoring approach, which includes ozone uptake as a cause variable, may provide the missing information on processes that are known to be important to risk assessment of ozone impacts on forest trees.
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